A method for controlling variability in power output of a wind farm supplying power to a grid includes monitoring a power output level of the wind farm. The monitored power output level is compared to a target power output level. A command is issued to increase or decrease electrical power consumption by an electrolyzer system electrically coupled to the wind farm to maintain a net power output level by the wind farm based upon the comparison.
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14. A method for controlling variability in power output of a renewable energy source supplying power to a grid, comprising:
monitoring a power output level of the renewable energy source and monitoring a rate of change of power output of the renewable energy source;
comparing the monitored power output level of the renewable energy source to a target power output level; and
commanding an increase or decrease of electrical power consumption by an electrolyzer system electrically coupled to the renewable energy source to maintain a net power output level by the renewable energy source based upon the comparison.
1. A method for controlling variability in power output of a wind farm supplying power to a grid, comprising:
monitoring a power output level of the wind farm;
comparing the monitored power output level of the wind farm to a target power output level;
commanding an increase or decrease of electrical power consumption by an electrolyzer system electrically coupled to the wind farm to maintain a net power output level by the wind farm based upon the comparison; and
monitoring a rate of change of power output by the wind farm and comparing the rate of change to a target rate of change of power output supplied to the grid.
7. A method for controlling a rate of change of net power output of a wind farm, comprising:
monitoring a rate of change of power output of the wind farm;
comparing the monitored rate of change of power output of the wind farm to a target rate of change of power output; and
commanding an increase or decrease of electrical power consumption by a electrolyzer system electrically coupled to the wind farm, wherein the electrolyzer system power consumption is commanded based upon the difference between the rate of change of total power output of the wind farm and the target rate of change of power output being supplied to a grid.
9. A method for controlling a ramp-down rate of net power output of a wind farm, comprising:
forecasting a reduction in power output of the wind farm due to reduced wind speeds based on a rate of change of power output of the wind farm;
ramping up electrical power consumption of an electrolyzer system electrically coupled to the wind farm in response to the forecast until an actual reduction in power output of the wind farm occurs; and
ramping down electrical power consumption of the electrolyzer system in response to the actual reduction of power output of the wind farm to maintain the ramp-down rate of net power output of the wind farm within a target ramp-down rate.
19. A method for controlling variability in power output of a wind farm supplying power to a grid, comprising:
monitoring a power output level of the wind farm;
comparing the monitored power output level of the wind farm to a target power output level;
commanding an increase or decrease of electrical power consumption by an electrolyzer system electrically coupled to the wind farm to maintain a net power output level by the wind farm based upon the comparison; and
monitoring a rate of change of power output by the wind farm and comparing the rate of change to a target rate of change of power output supplied to the grid,
wherein the target rate of change of power output supplied to the grid is based on allowable power ramp rates of one or more auxiliary power sources supplying power to the grid.
11. A wind power generation system, comprising:
a wind farm comprising a plurality of wind turbine generators operable to collectively supply electrical power to a grid;
an electrolyzer system electrically coupled to the wind farm and operable to consume variable quantities of power output by the wind farm; and
a wind farm management system operable to monitor a power output level of the wind farm, compare the monitored power output level of the wind farm to a target power output level, command an increase or decrease in electrical power consumption by the electrolyzer system to maintain a net power output level by the wind farm based upon the comparison, and monitor a rate of change of power output by the wind farm and compare the rate of chance to a target rate of change of power output supplied to the grid.
20. A method for controlling variability in power output of a wind farm supplying power to a grid, comprising:
monitoring a power output level of the wind farm;
comparing the monitored power output level of the wind farm to a target power output level;
commanding an increase or decrease of electrical power consumption by an electrolyzer system electrically coupled to the wind farm to maintain a net power output level by the wind farm based upon the comparison; and
monitoring a rate of change of power output by the wind farm and comparing the rate of change to a target rate of change of power output supplied to the grid,
wherein the electrolyzer system power consumption is commanded based upon the difference between a rate of change of total power output of the wind farm and the target rate of change of power output supplied to the grid.
21. A method for controlling variability in power output of a wind farm supplying power to a grid, comprising:
monitoring a power output level of the wind farm;
comparing the monitored power output level of the wind farm to a target power output level;
commanding an increase or decrease of electrical power consumption by an electrolyzer system electrically coupled to the wind farm to maintain a net power output level by the wind farm based upon the comparison; and
monitoring a rate of change of power output by the wind farm and comparing the rate of change to a target rate of change of power output supplied to the grid,
wherein monitoring the power output level of the wind farm further comprises:
sensing the power output level of the wind farm at successive points in time; and
determining a temporal average of sensed power output levels of the wind farm for a selected time window.
2. The method of
3. The method of
4. The method of
5. The method of
6. The method of
8. The method of
10. The method of
12. The wind power generation system of
power monitoring circuitry configured to determine temporally averaged power output and ramp rates of the wind farm;
a comparison module configured to compare the temporally averaged power output and ramp rates with a target power output and ramp rate; and
a load command module configured to generate an electrolyzer load command based on the comparison.
13. The wind power generation system of
17. The method of
18. The method of
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The invention relates generally to wind power generation, and more particularly, to techniques for controlling net power output level of a wind farm. Specific embodiments of the present technique facilitate control of the variability in power output levels of a wind farm by associating the power output of the wind farm to a variable electrical load, such as an electrolysis plant.
A wind power generation system generally includes a wind farm having a plurality of wind turbine generators supplying power to a utility grid or other end user. Wind turbine power output is known to experience relatively rapid variations due to changes in wind speed, such as during gusts. Collective power output of the wind farm is greatly influenced by wind conditions on individual wind turbine generators. The inherent inertia of individual wind turbines and the varied operating conditions of wind turbines across a large wind farm may contribute, to an extent, to smoothing of some variation in power output of the wind farm. However, given the changeable nature of winds, it is possible that the collective output of a wind farm can vary from relatively low output levels to full power, and vice versa, in relatively short periods of time. Because electrical power is not stored on the power generation system in any meaningful quantities, it is essential that there always be a balance between electricity generated and electricity consumed.
Utilities often have other power resources, such as thermal power plants to balance their electrical loads, thus accommodating variability in wind conditions during intermittent changes in wind conditions. Thermal power plants may include, for example, coal and gas fired stations. Power fluctuation of wind farms due to gusty or low wind conditions is usually dealt with by adjusting power output of these thermal power plants to provide relatively constant overall power matching demands on a grid system. Such adjustments may, for example, be facilitated by automatic governor response for short time frames, with deliberate dispatch adjustments acting over longer periods.
However, it is often difficult to change power output of thermal power plants instantaneously. Changing of power output may be also referred to as ramping. Thermal power generators desirably require a ramp rate that does not impose excessive thermal stresses, and that accommodates the natural lag times involved in heating and cooling the heat transfer components. As an example, coal-fired power stations may take over 12 hours to start from cold, and, even when hot, may take 2 to 3 hours to be ramped from 0–100% of their rated power. Ramping down of such thermal power generators requires similarly slow rates to minimize risk of damaging plant components. Wind conditions, on the other hand, may change drastically in a relatively shorter time span. It is, therefore, desirable to control power ramp rates of wind farms taking into consideration the maximum prescribed power ramp rates of such other power resources, so as not to require them to respond at higher than acceptable ramp rates.
It is possible to limit power output, and consequently power ramp-up rates of individual wind turbine generators at any level up to a maximum power available given the prevailing wind conditions. This is achieved by curtailing a portion of the power output, so that the power ramp rate does not exceed a maximum desired ramp rate. However this limits the capture of wind energy and increases the effective cost of energy of the wind farm. Similarly, in case of sudden fall in wind speeds, the output of the wind turbine generator may be controlled in a preemptive manner before the wind speed actually starts to fall, so that the power ramp-down rate is gradual and controlled to be within the ramp rate limits of the auxiliary power sources. Although useful as a means of controlling ramp rate, this again restricts power output of the wind turbine generator leading to a loss in wind energy capture.
There is, hence, a need for a technique to control effective power output levels at a wind farm level within limits and ramp rate restrictions prescribed by transmission system operators, while minimizing the loss of useful wind energy, and hence, the effective cost of energy.
The present technique accordingly provides a novel system and method to regulate effective power output of a variable power generation system, such as a wind turbine. Briefly, in accordance with one aspect of the present technique, a method for controlling variability in power output of a wind farm supplying power to a grid is provided. The method includes monitoring power output level of the wind farm. The monitored power output levels are compared to a target power output level. A command is issued to increase or decrease electrical power consumption by an electrolyzer system electrically coupled to the wind farm (either locally, or via a grid), to maintain a net power output level by the wind farm based upon the comparison.
In accordance with another aspect, a wind power generation system is provided. The wind power generation system includes a wind farm comprising a plurality of wind turbine generators and an electrolyzer system electrically coupled to the wind farm (either locally, or via a grid). The plurality of wind turbine generators is operable to collectively supply electrical power to a grid. The electrolyzer system is operable to consume variable quantities of power output by the wind farm. The wind power generation system further includes a wind farm management system operable to monitor power output level of the wind farm, compare the monitored power output level of the wind farm to a target power output level, and command an increase or decrease in electrical power consumption by the electrolyzer system to maintain a net power output level by the wind farm based upon the comparison.
In yet another aspect, a method for controlling variability in power output of a renewable energy source supplying power to a grid is provided. The renewable energy source may include, for example, a wind turbine, or a photovoltaic cell, among others. The method includes monitoring power output level of the renewable energy source. The monitored power output levels are compared to a target power output level. A command is issued to increase or decrease electrical power consumption by an electrolyzer system electrically coupled to the renewable energy source, to maintain a net power output level by the renewable energy source based upon the comparison.
These and other features, aspects, and advantages of the present invention will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
As discussed in detail below, embodiments of the present technique provide a system and method for associating a relatively time insensitive electrical load, such as an electrolysis plant, with a variable power generation system, so as to control the net output of the variable power generation system by controlling the load. In the embodiments illustrated, the variable power generation system includes a wind power generation system. However, other renewable energy generation systems, such as, for example, photovoltaic cells, which are subject to are subject to variability in the energy resource, are also within the scope of the present technique. Specific embodiments of the present technique are discussed below referring generally to
Turning now to the drawings,
In the illustrated embodiment, the net output 40 to the grid 20 is stabilized by associating the collective power output 36 of the wind farm 12 to a variable electrical load in the form an electrolyzer system 44. As will be appreciated by those skilled in the art, an electrolyzer system is operable to receive electrical power and water (H2O) as input and produce as output hydrogen (H2) and oxygen (O2) based on chemical transformation which may be summarized as below:
H2O=H++OH−;
2OH−=H2O+½O2+e−;
2H++2e−=H2.
In the illustrated embodiment of
In one mode of operation, the net power output 40 to the grid 20 may be held substantially constant by modulating the electrolyzer load to follow deviations in the collective wind farm power output 36 from a desired level acceptable to the grid. In another mode of operation the above principle may be extended to control rate-of-change of the net power output 40 to the grid 20 to match or remain within acceptable bounds with respect to a level that is compatible with ramp-up/ramp-down rates of the other power sources (e.g. primary fossil fuel or nuclear facilitates). In a still further mode of operation, by augmenting wind forecasting techniques to the power balancing mechanism provided by the present technique, it is possible to control power ramp-down rate of the wind farm 12 due to a sudden fall in speeds such that net ramp-down rate of the power output 40 supplied to the grid 20 is maintained within a target power ramp-down rate acceptable to the grid 20. Typically such rates are defined by regulations or power supply standards. Successful operation of the wind-farm electrolyzer combination may be achieved by logically associating the individual units, under a real-time control algorithm. Exemplary control algorithms for the above-discussed modes of operation are discussed in greater detail below with reference to
In the illustrated embodiment, the aforementioned control algorithm is incorporated in a wind farm management system 54 comprising a central controller. In accordance with aspects of the present technique, the controller is operable to modulate the power consumption of the electrolyzer based on instantaneous collective power output 36 of the wind farm 12, and predetermined set points or target values for the net power output 40 to the grid 20, and rate of change of the net power output 40. In certain embodiments, the wind farm management system 54 may be in data communication with individual wind turbine generators of the wind farm 12 and may be operable to control collective power output 36 of the wind farm 12 by controlling power ramp rates of individual wind turbine generators. In the illustrated embodiment, the wind farm management system 54 is operable monitor total power output 36 of the wind farm 12 and the net power 40 transmitted to the grid 20 via power sensors 56 and 58 respectively. Based on the monitored output power level, the wind farm management system is operable to command power consumption 52 by the electrolyzer load so as to maintain the net output 40 within desirable limits. The wind farm management system 54 may communicate load commands to the electrolyzer system 44 via communication links 60. The communication links 60 may include wired or wireless data transfer links including, for example, hardwired cables, private data networks, the Internet, and so forth. In response to these commands, load on the electrolyzer system 44 may be controlled by controlling the current density of current flowing through electrolyzer plates. As will be appreciated by those skilled in the art, controllability of current density may be achieved by controllable power electronic devices, such as rectifiers that convert the AC output of the wind farm into a DC input to the electrolyzer having controlled DC current magnitude. Appropriate sizing of the electrolyzer with respect to the wind generator allows for the benefits of the present technique to be applied on both rising and falling wind power generation. The wind farm management system 54 may further be operable to communicate with power regulation circuitry 61 to distribute power between the grid 20 and the electrolyzer system 44 based on the generated electrolyzer command.
The above-described mode of operation is best illustrated via a graphical representation of power output as shown in
The above-described mode of operation is illustrated via a graphical representation of power output as shown in
Aspects of the present technique may also be incorporated to provide a method to control ramp-down rate of net grid power output due to a sudden fall in wind speed.
The techniques discussed above thus advantageously facilitate regulation of net electrical power output of a variable power generation system without curtailing power output of the system. Although the present technique has been embodied on a wind power generation system, it should be appreciated that use of a variable electrolyzer load may be incorporated to stabilize power output of other renewable energy sources, such as, for example, photovoltaic cells. Embodiments of the present techniques further facilitate observance of grid power ramp rate limits without loss of effective wind energy capture. The illustrated embodiments thus facilitate a higher penetration of wind power on to electricity networks.
While only certain features of the invention have been illustrated and described herein, many modifications and changes will occur to those skilled in the art. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the invention.
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